SU1735828A1 - Microclimate regulator - Google Patents

Abstract

The invention makes it possible to reduce the waste of products by improving the quality of microclimate control. The device contains sensors of air speed 1, air temperature 2, wall surface temperature 3, in contact with air flow, relative humidity 4, ambient temperature sensor 5, square root extraction unit 6, first 7, second 8, third 9 multiplicators, the first 11, the second 12, the third 16 units of comparison, the first 11, the second 15 adders, the setpoint generator of the ambient temperature 13, the functional unit 14, which is used to calculate the moisture content of indoor air, the setting unit of the microclimate indicator 17 omeschenii, temperature controller 18, the electric heater 19. The function block 14 comprises serially connected fourth and fifth blocks multiplication, division unit and the fourth adder. 2 Il.

Description

The invention relates to the automatic control of the microclimate in enclosed spaces and can be used in the production of electronic, instrument-making and other industries.

A device for controlling the microclimate is known, comprising a series-connected setting unit, a comparison unit, a temperature controller, an actuator and temperature sensors connected to the output of an adder, each temperature sensor connected to the cathode of the corresponding diode, the anodes of which are connected via an additional variable resistor and through an additionally installed deadband-type circuit to one of the outputs of the comparison circuit, the other input of which is through deli The voltage supply is connected to the output of the adder 1.

The disadvantage of this device is that, to ensure comfort, the relationship between the air temperature in the room, the wall surface temperature, humidity, air speed and ambient temperature outside the room is not taken into account, which reduces the room comfort.

The closest to the technical essence and the achieved effect to the proposed is a device for controlling the temperature in different rooms, containing sensors for air temperature in the room, wall surface temperature, temperature controller associated with an adjustable current source 2.

A disadvantage of the known device is that when regulating the temperature in the room, the cumulative effect on the microclimate of humidity and air velocity, ambient temperature and the microclimate index set for this room, which reduces the comfort of the room, is not taken into account.

The aim of the invention is to increase the comfort of the room.

The goal is achieved by the device for controlling the microclimate containing indoor speed sensors of air movement, air temperature, temperature of wall surfaces in contact with air, and air humidity connected respectively to the input of the square root extractor unit to the combined first inputs of the first the comparison unit and the first adder, to the second input of the first adder, the input of the functional imager, the first multiplication unit, the second and third multiplication units Connected by the first inputs to the outputs

respectively, the square root extraction unit, the first comparison unit and the first adder, the outputs of the first and third multiplication units and the functional generator are connected to the inputs of the second

0 the adder, the output of the second multiplication unit is connected to the second input of the first multiplication unit, and the second inputs of the second and third multiplication units are connected to the outputs of the corresponding set factors and the temperature controller connected with the actuator of the heater contains the sensor and the setting unit ambient temperatures connected to the inputs of the second comparison unit,

0 and serially connected microclimate indicator in the room and the third comparison unit, the output connected to the input of the temperature controller, and the second input to the output of the second sum 5 torus, while the output of the second comparison unit is connected to the third input of the first adder and the correcting input of the first comparison unit .

FIG. 1 is a block diagram of a device for climate control; in fig. 2 is a block diagram of an embodiment of the functional formation used in the device.

The device contains speed sensors

5 air movement 1, air temperature 2, temperature 3 of the wall surface in contact with the air flow, humidity 4 air installed inside the room (in FIG. 1, the technological volume of the room is outlined in dotted lines), ambient temperature sensor 5, square root extractor 6 associated with the output of sensor 1, the first 7, second 8, third 9 multiplication units, the first comparison unit 10, the output of which is connected to the input of the second multiplication unit 8 connected to the input of the first multiplication unit 7, the first adder 11, whose inputs united with the outputs of the sensor 2 air temperature sensor

0 3 wall surfaces in contact with the air flow, the second comparison unit 12, one input of which is connected to the ambient temperature sensor 5, and the other input to the setting unit 13 of the ambient temperature, the output of the second comparison unit 12 is connected to the second input of the first block 10 comparison, functional shaper 14, used to calculate the moisture content of the air in the room, the input of which is connected to the output of the sensor 4 of the humidity of the air in the room, the output of the functional shaper 14 is connected to the input of the second sum torus 15, the other two inputs of which are connected to the outputs of the first 7 and third 9 multiplication blocks, the output of the second adder 15 is connected to the input of the third block

16, the other input of which is connected to the output of the indoor climate indicator 17, the temperature controller 18, the input of which is connected to the output of the third comparison unit 16, and the output connected to the input of the electric heater actuator 19.

The functional driver 14 contains fourth multiply-connected fourth 20, fifth 21 multipliers and division block 22, the second input of which is connected to the output of the fourth adder 23, the first input of which receives as a setpoint a signal corresponding to barometric air pressure and the second input is connected to the output the fourth multiplication unit 20, the first input of which is connected to the output of the relative humidity sensor 4 and is the input of the functional imaging unit 14, to the second inputs of the fourth 2Q and fifth 21 smart blocks Augments come as constant multipliers, the value of water vapor saturation pressure and a coefficient value of 62.2. The output of dividing unit 22 is the output of functional shaper 14.

The device works as follows.

Before starting work on the setter 13, a daily change in the ambient temperature is established taking into account the warm or cold period of the year. On the setter

17 establishes the value of the microclimate indicator taking into account the requirements of technology and the comfortable conditions of the production premises. Sensors 1–4 monitor the microclimate parameters in the room. The current value of the microclimate indicator is fed to the input of the third comparison unit 16, where it is compared with a predetermined value. The error signal from the output of the third comparison unit 16 is fed to the temperature controller 18, which controls the heater 19, turning it on at the minimum value of the specified climate indicator and turning it off at the maximum, i.e. carried out the automatic maintenance of the microclimate in accordance with the value of the setting device 17. At the same time, using the sensor 5, it monitors the ambient temperature outside the room. The output signal of the temperature sensor 5 is fed to the input of the second comparison unit 12, where it is compared with the temperature setpoint from the output of the setpoint generator.

13 to the second input of unit 12 comparison. As a result of the destabilizing factors, the resulting error signal from the output of the comparison unit 12 is fed to one of the inputs of the first block 10

0 comparison and the first adder 11, the other inputs of which receive signals from the output of sensor 2 of air temperature and from the output of sensor 3 of wall surface temperature in contact with the air medium

5 The resulting signal from the output of the first adder 11, is proportional to the sum of the air temperature, the surface temperature and the mismatch between the ambient temperature and its specified

0 value, is fed to the input of the third multiplier 9, where it is multiplied by a given constant coefficient equal to 0.24, and from the output of this block goes to one of the inputs of the second adder 15. The signal from the output of the stroke of the first comparison block 10 is proportional to the sum of the constant value (37,) of the air temperature and the mismatch between the ambient temperature and its specified value

0 to the input of the second multiplication unit 8, where it is multiplied by a factor of 0.09, and from the output of this unit goes to one of the inputs of the first multiplication unit 7, where it is multiplied with the output signal of unit 6

5 square root extraction. The output signal of the first multiplication unit 7 is fed to one of the inputs of the second adder 15. The input proportional to the value of the second adder 15 also arrives.

0 moisture content from the output of the functional former 14, which, using the relative humidity of the air in the room measured by sensor 4, calculates the moisture content. For

5 of this, the signal corresponding to the value of saturation pressure and arriving at the second input of multiplication unit 20 is multiplied with the signal corresponding to the relative humidity of the air in the room,

0 measured by the sensor 14. The output signal of the multiplication unit 20 is supplied to the first input of the fifth multiplication unit 21, where it is multiplied by a constant coefficient equal to 62.2, and from the output of the unit 21 it goes to

5, the first input of dividing unit 22. At the same time, a signal proportional to the product of relative humidity and saturation pressure is fed to one of the inputs of the fourth adder 23, where it is subtracted from the setpoint signal corresponding to the barometric air pressure. A signal proportional to the difference of the signals arriving at the inputs of the fourth adder 23 from the output of the fourth adder 23 is fed to the second input of the division unit 22. The resulting signal at the output of dividing unit 22, proportional to the moisture content of the air in the room and being the output of the functional shaper 14, is fed to one of the inputs of the second adder 15. Using the incoming signals, the output of the second adder 15 produces a signal proportional to the current microclimate indicator, which is fed to the input of the third comparison unit 16, where it is compared with a predetermined value. Heat generation at the indoor workplace and redistribution of heat transfer fluxes due to external disturbances lead to deviations of the air temperature in the room measured by sensor 2 from the optimum, and fluctuations in ambient temperature measured by sensor 5 of the temperature lead in addition to temperature deviations indoors from a given and mismatch at the output of the comparison unit 12. This mismatch is fed to the correction input of the first comparison unit 10 and to the correction input of the first adder 11 as an additional signal to the signals arriving at the other inputs of these blocks from the output of air temperature sensor 2 and air surface temperature sensor 3 in contact with the air medium. The presence of mismatches in the resultant output signals of the first comparator unit 10 and the first adder 11 at appropriate values of air velocity, air temperature, wall surface temperature, and relative humidity, measured respectively by sensors 1-4, leads to a deviation of the current value of the microclimate index generated by the output of the second adder 15, from the specified value. Occurs at the output of the second block

16, the mismatch signal is fed to the input of the controller 18, which, taking into account the mismatch sign, controls the executive body of the electric heater 19, thereby bringing the indoor climate to a predetermined value.

Claims (1)

Claims An apparatus for controlling the microclimate comprising indoor sensors for air velocity, air temperature, wall surface temperature in contact with air, and air humidity, connected respectively to the inlet of the square root unit, to the combined first inputs of the first comparison unit and the first adder, to the second input of the first adder, the functional input the former, the first multiplication unit, the second and third multiplication units, connected by the first inputs to the outputs, respectively, of the square root extraction unit, the first comparison unit and the first the adder, the outputs of the first and third multiplication units and the functional driver are connected to the inputs of the second adder, the output of the second multiplication unit is connected to the second input of the first unit multiplication, and the second inputs of the second and third multiplication units are associated with the outputs of the respective factor adjusters, as well as the temperature controller, output connected with the executive body A heater, characterized in that, in order to increase the comfort of the room, the device comprises an ambient temperature sensor and a setpoint controller connected to the inputs of the second comparison unit, and the indoor climate indicator unit and the third comparison unit, connected in series with the temperature controller input, and the second input with the output of the second adder, and the output of the second comparator unit with the third input of the first adder and the corrective input of the first comparison unit. FIG. 2